about
Immobilization of Monolayers Incorporating Cu Funnel Complexes onto Gold Electrodes. Application to the Selective Electrochemical Recognition of Primary Alkylamines in WaterCoordination of lead(II) in the supramolecular environment provided by a "two-story" calix[6]arene-based N6 ligand.Primary amine recognition in water by a calix[6]aza-cryptand incorporated in dodecylphosphocholine micelles.Calix[6]tren and copper(II): a third generation of funnel complexes on the way to redox calix-zymes.Synthesis and studies of a water-soluble and air-stable Cu(I)/Cu(II) open-shell funnel complex.Molecular recognition and self-assembly special feature: Multipoint molecular recognition within a calix[6]arene funnel complex.Biomimetic and self-assembled calix[6]arene-based receptors for neutral molecules.Supramolecular control of transition metal complexes in water by a hydrophobic cavity: a bio-inspired strategy.Supramolecular modeling of mono-copper enzyme active sites with calix[6]arene-based funnel complexes.Directional control and supramolecular protection allowing the chemo- and regioselective transformation of a triamine.First C3v-symmetrical calix[6](aza)crown.Unprecedented selective ipso-nitration of calixarenes monitored by the O-substituents.Investigation of the hydroxylation mechanism of noncoupled copper oxygenases by ab initio molecular dynamics simulations.Replacement of a nitrogen by a phosphorus donor in biomimetic copper complexes: a surprising and informative case study with calix[6]arene-based cryptands.Selective hetero-trisfunctionalization of the large rim of a biomimetic calix[6]arene using host-guest chemistry as a synthetic tool.Spectacular induced-fit process for guest binding by a calix[6]arene Zn(II) funnel complex."Two-Story" Calix[6]arene-Based Zinc and Copper Complexes: Structure, Properties, and O2 Binding.Mimicking the Regulation Step of Fe-Monooxygenases: Allosteric Modulation of FeIV -Oxo Formation by Guest Binding in a Dinuclear ZnII -FeII Calix[6]arene-Based Funnel Complex.Polarizing a hydrophobic cavity for the efficient binding of organic guests: the case of calix[6]tren, a highly efficient and versatile receptor for neutral or cationic species.Theoretical exploration of the oxidative properties of a [(tren Me1)CuO2]+ adduct relevant to copper monooxygenase enzymes: insights into competitive dehydrogenation versus hydroxylation reaction pathways.X-ray diffraction and EXAFS studies of hydroxo-Cu(II) complexes based on a calix[6]arene-N3 ligand: evidence for a mononuclear-dinuclear equilibrium controlled by supramolecular features.Supramolecular control of a mononuclear biomimetic copper(II) center: bowl complexes vs funnel complexes.Locally induced and self-induced "electroclick" onto a self-assembled monolayer: writing and reading with SECM under unbiased conditions.Selective EPR Detection of Primary Amines in Water with a Calix[6]azacryptand-Based Copper(II) Funnel Complex.Kinetic and Thermodynamic Stabilization of Metal Complexes by Introverted Coordination in a Calix[6]azacryptand.Supramolecular assistance for the selective demethylation of calixarene-based receptors.The first water-soluble bowl complex: molecular recognition of acetate by the biomimetic tris(imidazole) Zn(II) system at pH 7.4.Supramolecular assistance for the selective monofunctionalization of a calix[6]arene tris-carboxylic acid-based receptor.Selective Fluorimetric Detection of Primary Alkylamines by a Calix[6]arene Funnel Complex.Triflate-functionalized calix[6]arenes as versatile building-blocks: application to the synthesis of an inherently chiral Zn(ii) complex.Gating the electron transfer at a monocopper centre through the supramolecular coordination of water molecules within a protein chamber mimicIpso-Chlorosulfonylation of Calixarenes: A Powerful Tool for the Selective Functionalization of the Large RimIron Coordination Chemistry with New Ligands Containing Triazole and Pyridine Moieties. Comparison of the Coordination Ability of the N-DonorsElectrografting of calix[4]arenediazonium salts to form versatile robust platforms for spatially controlled surface functionalizationNovel biomimetic calix[6]arene-based copper(II) complexesSupramolecular stabilization of a tris(imidazolyl) Zn-aqua complex evidenced by X-ray analysis: a structural model for mono-zinc active sites of enzymesThe first water-soluble copper(I) calix[6]arene complex presenting a hydrophobic ligand binding pocket: a remarkable model for active sites in metalloenzymesAllosteric tuning of the intra-cavity binding properties of a calix[6]arene through external binding to a ZnII center coordinated to amino side chainsEncapsulation of a (H3O2)- unit in the aromatic core of a calix[6]arene closed by two Zn(II) ions at the small and large rimsInsights into the binding properties of a cuprous ion embedded in the tren cap of a calix[6]arene and supramolecular trapping of an intermediate
P50
Q28468197-908C396E-9730-49CA-8417-050CC2B0928FQ30698024-AAD54352-A122-4CDD-9DEB-814429A43726Q30884601-079E95F2-15BC-476A-8FA1-88CDD50EDD40Q33784454-FDC470F5-592F-440D-A3CD-72119A9AC1F9Q34255101-49E0A797-310C-4905-939D-2CEFF6B7BADCQ37250055-4F7EF237-6316-49B9-BDD1-1CC1F098410FQ37510650-36492651-31BA-48B6-823B-7CEA8ADDA7C2Q38327131-6B9EAB63-3C61-4DD7-8ED7-41B34D0BB89EQ40807228-FB6945AD-8DCF-4561-B63D-C2201904A32CQ43272165-23E5B7DA-2DEC-4C62-957D-FDC9432C92F3Q44415986-6AA4D4DD-2E8A-46D2-A604-A3E295F6E86AQ44567033-E5CD5C46-8899-41A2-9521-807D658B81DBQ45527739-BDD0F107-8524-4D03-936B-3BB6756C85FFQ46020277-C408D7B7-C0A4-4791-8555-5B5229166FE2Q46298378-D217CE54-E115-41AE-B709-3AE4E5EBCA52Q46309143-5435D703-8671-41B7-996D-E0A5ECE2BDBCQ46314607-A7780951-EA93-42F7-A811-4AA28337C773Q46426867-30F31CE0-3D25-49D1-B630-3A1388978DB6Q46532536-A17AFD6A-2270-4ECC-80BF-B4FF92BDEFBEQ46567526-3CB8CDF1-70FB-44F9-9BD1-853D85A69642Q46858226-502FC04F-8F3B-4D78-AD95-D2A3E83A727DQ46883801-3D4C0A1A-A66F-4583-AFA8-809F05EA4E6FQ46913768-12397F4B-8A1F-4613-9AA0-0889CE47D94FQ47725293-BBB9D103-BD01-4A74-B62A-682D6C3CAEA8Q48229319-29EC2D0F-449F-4584-8BE0-73C6ACF72F16Q50989139-7D1A5D8B-7F26-4D2F-A479-2EA8BDD4661FQ51010297-529B14BE-9579-4023-A6E6-B4A01B94C902Q51772960-85E998FF-D27C-46D2-83D6-67C46A2298DDQ52692363-B9883112-F07E-4630-80A1-BF4FBF2A103FQ53326110-8D982E01-8587-4E2E-8DA4-5566F9F3C570Q57599391-DBC9CFE4-27EF-4304-9FD1-4F9DBF5B3F26Q57707662-7EE58DAA-06E7-4B63-AB81-08FA9D556D22Q61164813-47FE5531-A305-469D-9A89-BAD16929D4EFQ61207358-48586486-4B55-4C81-9129-E6DA3288E167Q73484283-FF228BCE-1724-43DD-B45B-7EECC4C353C9Q74409390-DB7FC8CC-45EB-43DB-8743-FCC5D935A5E4Q78687572-65FBA3C9-3D53-4509-8317-DDEEC3DB559CQ79402303-6E9939DE-A333-4938-9920-0DC3DB6B15E8Q79703028-D108E9AA-5EB1-4355-A367-79769B684119Q79721691-3953A5C5-5C02-4AEA-920C-7A73E589DE33
P50
description
hulumtuese
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Olivia Reinaud
@ast
Olivia Reinaud
@en
Olivia Reinaud
@es
Olivia Reinaud
@fr
Olivia Reinaud
@nl
type
label
Olivia Reinaud
@ast
Olivia Reinaud
@en
Olivia Reinaud
@es
Olivia Reinaud
@fr
Olivia Reinaud
@nl
prefLabel
Olivia Reinaud
@ast
Olivia Reinaud
@en
Olivia Reinaud
@es
Olivia Reinaud
@fr
Olivia Reinaud
@nl
P214
P268
P269
P1053
G-5886-2019
P106
P2038
Olivia_Reinaud
P21
P213
0000 0003 8180 3122
P214
P268
P269
P31
P3829
P4012
P496
0000-0002-2600-5331
P569
1960-09-06T00:00:00Z
P6634
olivia-reinaud-a84b01121
P735
P7859
viaf-262021064